This wide-field image shows the Milky Way stretching across the southern sky. The beautiful Carina Nebula (NGC 3372) is seen at the right of the image glowing in red. It is within this spiral arm of our Milky Way that the bright star cluster NGC 3603 resides. At the centre of the image is the constellation of Crux (The Southern Cross). The bright yellow/white star at the left of the image is Alpha Centauri, in fact a system of three stars, at a distance of about 4.4 light-years from Earth. The star Alpha Centauri C, Proxima Centauri, is the closest star to the Solar System.

Proxima Centauri is a low mass red dwarf, and is part of a triple system, the other two stars being α Centauri A and B, which are solar like stars in a close orbit around each other.

3D map of all known stellar systems in the solar neighbourhood within a radius of 12.5 light-years. The Sun is at the centre. The colour is indicative of the temperature and the spectral class — white stars are (main-sequence) A and F dwarfs; yellow stars like the Sun are G dwarfs; orange stars are K dwarfs; and red stars are M dwarfs, by far the most common type of star in the solar neighbourhood. The blue axes are oriented along the galactic coordinate system, and the radii of the rings are 5, 10, and 15 light-years, respectively.

The whole system is a little over 4 light years away, the nearest stars to the Sun, and Proxima is the closest of the three stars.

This image of the sky around the bright star Alpha Centauri AB also shows the much fainter red dwarf star, Proxima Centauri, the closest star to the Solar System. The picture was created from pictures forming part of the Digitized Sky Survey 2. The blue halo around Alpha Centauri AB is an artifact of the photographic process, the star is really pale yellow in colour like the Sun.

This picture combines a view of the southern skies over the ESO 3.6-metre telescope at the La Silla Observatory in Chile with images of the stars Proxima Centauri (lower-right) and the double star Alpha Centauri AB (lower-left) from the NASA/ESA Hubble Space Telescope. Proxima Centauri is the closest star to the Solar System and is orbited by the planet Proxima b, which was discovered using the HARPS instrument on the ESO 3.6-metre telescope.

It may have been noise. α Cen A and B were in conjunction, making them hard to observe, but are now separating, and observing campaigns to look for planets around those star are continuing.

ESO researchers, using the radial velocity variability technique, have detected a quite robust signature of a planet with a mass of 1.3 Earth masses, or more, in a 11 day orbit around Proxima Centauri.

This plot shows how the motion of Proxima Centauri towards and away from Earth is changing with time over the first half of 2016. Sometimes Proxima Centauri is approaching Earth at about 5 kilometres per hour — normal human walking pace — and at times receding at the same speed. This regular pattern of changing radial velocities repeats with a period of 11.2 days. Careful analysis of the resulting tiny Doppler shifts showed that they indicated the presence of a planet with a mass at least 1.3 times that of the Earth, orbiting about 7 million kilometres from Proxima Centauri — only 5% of the Earth-Sun distance.

Since the Proxima Centauri is almost 1,000 times fainter than the Sun, this puts the putative planet well within the habitable zone of the star, near the inner edge of the zone, but formally inside it.

This infographic compares the orbit of the planet around Proxima Centauri (Proxima b) with the same region of the Solar System. Proxima Centauri is smaller and cooler than the Sun and the planet orbits much closer to its star than Mercury. As a result it lies well within the habitable zone, where liquid water can exist on the planet’s surface.

The planet would most likely be tidally locked to the star, and might either have one face locked to the star (like the Moon to the Earth), or, conceivable, be in a 2:3 tidal lock, like Mercury is with the Sun.
In either case, it is conceivable for this planet to have liquid water on its surface, IF it is has reasonable thickness atmosphere of nice enough composition.

This artist’s impression shows the planet Proxima b orbiting the red dwarf star Proxima Centauri, the closest star to the Solar System. The double star Alpha Centauri AB also appears in the image between the planet and Proxima itself. Proxima b is a little more massive than the Earth and orbits in the habitable zone around Proxima Centauri, where the temperature is suitable for liquid water to exist on its surface.

This is the nearest star to the Sun.

The relative sizes of a number of objects, including the three (known) members of Alpha Centauri triple system and some other stars for which the angular sizes have also been measured with the Very Large Telescope Interferometer (VLTI) at the ESO Paranal Observatory. The Sun and planet Jupiter are also shown for comparison.

It has an Earth like planet orbiting in a nice orbit.
It will be about as easy to characterise as any exoplanet ever.
There really are a lot of exoplanets everywhere, and a lot of them are Earth mass, and a lot of those are in nice orbits.

What a nice Universe.

Next, a nice intense workshop on how to find lots of low mass planets in the habitable zones of lots of stars in the near future.
Should be a fun workshop.

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I have a question. For human and other life to exist, we need elements heavier than Fe. Based upon my knowledge of nucleosynthesis, in order for elements heavier than Fe to exist, the system must be formed from the remnants of a supernova. With some "hand-waving" one can argue that elements up to Pb might not require a supernova to exist. But Iodine which is needed for human life, and can only be formed from a supernova event.

So my question, was Proxima Centauri formed from the remnants of a supernova event? I vaguely remember reading somewhere that Alpha Centauri was NOT made formed from a supernova event.

The elements with atomic number higher than Fe do indeed primarily come from (type II) supernovae.
The Centauri stellar system is about the same age as the Solar System and actually a little bit more rich in metals. We are not certain if Proxima Centauri is a sibling of α Cen A and B, and it is surprisingly hard to measure its true composition directly, bit it is also quite metal rich.
It did not form directly from a supernova (nor did the Solar System, rather we think the Solar System formation was triggered by the shock from a nearby supernova which added some additional metal debris to the already metal rich gas from which the Solar System formed), but the Centauri system formed from gas which already contained some of the metal debris from dozens of previous generations of supernovae. This would certainly have included, for example, iodine, and in fact we see the spectroscopic signature of essentially all the elements in roughly solar abundance in the Centauri stars. The abundances differ in detail, which is interesting and tells us about the origin and age of the stars, but the composition is approximately the same as that of the Solar System to within about a factor of 2 in most elemental abundances.
Hope that helps.

I gather Stephen Baxter also just did a novel premised on a habitable planet orbiting Prox Cen - called, strangely enough, "Proxima", or so Alastair Reynolds tells me... haven't read it. There is also the old Murray Leinster story about man eating Centaurian intelligent plants...

Thanks for the response. If Iodine is there, then we can survive, although we might need to bring our own artificial lights, for plant life, and for getting a decent tan. I am not sure how much UV a Red Dwarf would output.

Well, first we have to find out what the actual mass and radius of the planet are, and if it has an atmosphere.
There is some hard UV, but not much blue light - interesting tweetstorm on what that means going on right now.

Starshot is planning on leaving for Prox Cen within 20 years, and taking less than 20 years to get there... but unless you can upload to a chip, it won't be taking passengers for a while.

With respect to the Sun, hard UV and X rays are correlated with sunspot activity. I don't know specifically about Proxima Centauri, but many M-class dwarfs show evidence of a strong stellar activity cycle. That might still be OK if the planet has a sufficiently strong intrinsic magnetic field, but if not you don't want to live on the dayside of this planet because stellar energetic particle events will fry you. Even with a magnetic field, you wouldn't want to get too close to the magnetic cusps, for the same reason.

Prox Cen is active - it is moderately active for an M dwarf, with Lx/Lbol ~ 10^-4, with significant flaring. It is apparently a slow rotator, with a measured rotation period of 84 d and a tentative suggestion of magnetic cycle of 7 yrs, but this is challenged in the literature. For a slow rotator the activity is at the high end of the range of activity but not wildly high. There is a discussion in social media about whether the rotation period could be 11 days and the planet signal is actually sunspots. This is a real concern, but there is a careful photometric analysis which shows no power around 5-15 d window and it is very hard to see how you could hide the rotation that well and yet also have it be strong enough to show in the RV.
Particle events would be a concern for possibility of life, and both magnetic field and atmosphere would be critical. Both are in principle measurable...

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